// g2o - General Graph Optimization
// Copyright (C) 2011 H. Strasdat, G. Grisetti, R. Kümmerle, W. Burgard
// All rights reserved.
//
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// modification, are permitted provided that the following conditions are
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//
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#ifndef G2O_ISOMETRY3D_MAPPINGS_H_
#define G2O_ISOMETRY3D_MAPPINGS_H_

#include <Eigen/Core>

#include "g2o_types_slam3d_api.h"
#include "se3quat.h"

namespace g2o {

/**
 * internal functions used inside g2o.
 * Those functions may disappear or change their meaning without further
 * notification
 */
namespace internal {

/**
 * extract the rotation matrix from an Isometry3 matrix. Eigen itself
 * performs an SVD decomposition to recover the nearest orthogonal matrix,
 * since its rotation() function also handles a scaling matrix.  An Isometry3
 * does not have a scaling portion and we assume that the Isometry3 is
 * numerically stable while we compute the error and the Jacobians.  Hence,
 * we directly extract the rotation block out of the full matrix.
 *
 * Note, we could also call .linear() on the Isometry3. However, I dislike
 * the name of that function a bit.
 */
inline Isometry3::ConstLinearPart extractRotation(const Isometry3& A) {
  return A.matrix().topLeftCorner<3, 3>();
}

/**
 * computes the nearest orthogonal matrix of a rotation matrix which might
 * be affected by numerical inaccuracies. We periodically call this function
 * after performinag a large number of updates on vertices.
 * This function computes an SVD to reconstruct the nearest orthogonal matrix.
 */
template <typename Derived>
void nearestOrthogonalMatrix(const Eigen::MatrixBase<Derived>& R) {
  Eigen::JacobiSVD<Matrix3> svd(R, Eigen::ComputeFullU | Eigen::ComputeFullV);
  number_t det = (svd.matrixU() * svd.matrixV().adjoint()).determinant();
  Matrix3 scaledU(svd.matrixU());
  scaledU.col(0) /= det;
  const_cast<Eigen::MatrixBase<Derived>&>(R) =
      scaledU * svd.matrixV().transpose();
}

/**
 * compute a fast approximation for the nearest orthogonal rotation matrix.
 * The function computes the residual E = RR^T - I which is then used as
 * follows: R := R - 1/2 R E
 */
template <typename Derived>
void approximateNearestOrthogonalMatrix(const Eigen::MatrixBase<Derived>& R) {
  Matrix3 E = R.transpose() * R;
  E.diagonal().array() -= 1;
  const_cast<Eigen::MatrixBase<Derived>&>(R) -= 0.5 * R * E;
}

/**
 * normalize the quaternion, such that ||q|| == 1 and q.w() > 0
 */
G2O_TYPES_SLAM3D_API Quaternion normalized(const Quaternion& q);
/**
 * as above, but in-place
 */
G2O_TYPES_SLAM3D_API Quaternion& normalize(Quaternion& q);

// functions to handle the rotation part
/**
 * Rotation matrix -> Euler angles (roll, pitch, yaw)
 */
G2O_TYPES_SLAM3D_API Vector3 toEuler(const Matrix3& R);
/**
 * Euler angles (roll, pitch, yaw) -> Rotation matrix
 */
G2O_TYPES_SLAM3D_API Matrix3 fromEuler(const Vector3& v);
/**
 * Rotation matrix -> (qx qy, qz)
 */
G2O_TYPES_SLAM3D_API Vector3 toCompactQuaternion(const Matrix3& R);
/**
 * (qx qy, qz) -> Rotation matrix, whereas (qx, qy, qz) are assumed to be
 * part of a quaternion which was normalized with the function above.
 */
G2O_TYPES_SLAM3D_API Matrix3 fromCompactQuaternion(const Vector3& v);

// functions to handle the toVector of the whole transformations
/**
 * Isometry3 -> (x, y, z, qx, qy, qz)
 */
G2O_TYPES_SLAM3D_API Vector6 toVectorMQT(const Isometry3& t);
/**
 * Isometry3 -> (x, y, z, roll, pitch, yaw)
 */
G2O_TYPES_SLAM3D_API Vector6 toVectorET(const Isometry3& t);
/**
 * Isometry3 -> (x, y, z, qx, qy, qz, qw)
 */
G2O_TYPES_SLAM3D_API Vector7 toVectorQT(const Isometry3& t);

/**
 * (x, y, z, qx, qy, qz) -> Isometry3
 */
G2O_TYPES_SLAM3D_API Isometry3 fromVectorMQT(const Vector6& v);
/**
 * (x, y, z, roll, pitch, yaw) -> Isometry3
 */
G2O_TYPES_SLAM3D_API Isometry3 fromVectorET(const Vector6& v);
/**
 * (x, y, z, qx, qy, qz, qw) -> Isometry3
 */
G2O_TYPES_SLAM3D_API Isometry3 fromVectorQT(const Vector7& v);

/**
 * convert an Isometry3 to the old SE3Quat class
 */
G2O_TYPES_SLAM3D_API SE3Quat toSE3Quat(const Isometry3& t);
/**
 * convert from an old SE3Quat into Isometry3
 */
G2O_TYPES_SLAM3D_API Isometry3 fromSE3Quat(const SE3Quat& t);

}  // end namespace internal
}  // end namespace g2o

#endif
